An electrostatic discharge robust semiconductor transistor (transistor) includes a semiconductor substrate of a first conductivity type, a substrate contact region of the first conductivity type coupled with the semiconductor substrate, a source region of a second conductivity type, a channel region of the second conductivity type, a gate region of the first conductivity type, a drain region having a first drain region of the first conductivity type and a second drain region of the second conductivity type, and an electrical conductor coupled over the second drain region and a portion of the first drain region. A portion of the first drain region not covered by the electrical conductor forms a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses. In implementations the transistor includes a silicon controlled rectifier (SCR) junction field effect transistor (SCR JFET) or a laterally diffused metal-oxide semiconductor (SCR LDMOS).
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1. An electrostatic discharge robust semiconductor transistor, comprising:
a semiconductor substrate of a first conductivity type;
a substrate contact region of the first conductivity type coupled with the semiconductor substrate;
a source region of a second conductivity type coupled with the semiconductor substrate;
a channel region of the second conductivity type;
a gate region of the first conductivity type;
a drain region comprising a first drain region of the first conductivity type and a second drain region of the second conductivity type, and;
an electrical conductor directly coupled to and over the second drain region and a portion of the first drain region;
wherein a portion of the first drain region is not covered by the electrical conductor and becomes a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and;
wherein the transistor comprises a silicon controlled rectifier junction field effect transistor (SCR JFET).
15. An electrostatic discharge robust semiconductor transistor, comprising:
a semiconductor substrate of a first conductivity type;
a first substrate contact region of the first conductivity type coupled with the semiconductor substrate;
a source region of a second conductivity type coupled with the semiconductor substrate;
a channel region of the second conductivity type;
a gate region of the first conductivity type;
a drain region comprising a first drain region of the first conductivity type and a second drain region of the second conductivity type;
an electrically insulative region between the drain region and the gate region; and
an electrical conductor directly coupled over the second drain region and a portion of the first drain region;
wherein a portion of the first drain region is not covered by the electrical conductor and becomes a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and;
wherein the transistor comprises a silicon controlled rectifier junction field effect transistor (SCR JFET).
8. An electrostatic discharge robust semiconductor transistor, comprising:
a semiconductor substrate of a first conductivity type;
a first substrate contact region of the first conductivity type coupled with the semiconductor substrate;
a source region of a second conductivity type coupled with the semiconductor substrate;
a channel region of the second conductivity type;
a gate region of the first conductivity type;
a drain region comprising a first drain region of the first conductivity type and a second drain region of the second conductivity type;
a second substrate contact region of the second conductivity type coupled with the semiconductor substrate, and;
an electrical conductor directly coupled to and over the second drain region and a portion of the first drain region;
wherein a portion of the first drain region is not covered by the electrical conductor and becomes a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and;
wherein the transistor comprises a silicon controlled rectifier junction field effect transistor (SCR JFET).
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1. Technical Field
Aspects of this document relate generally to semiconductor transistors.
2. Background Art
A semiconductor transistor is a device used to amplify and/or switch an electronic signal. Semiconductor transistors may be subject to damage or altered behavior due to electrostatic discharge (ESD). There are a variety of models/standards that are used for designing and testing against transistor failure due to electrostatic discharge. These include the human body model (HBM), the charge device model (CDM) and the machine model (MM). The HBM simulates ESD due to discharge from a human being. The CDM simulates a charged device's discharge when it contacts a conductor. The MM simulates discharge from a non-human source to the device, such as from production equipment or a tool.
Implementations of an electrostatic discharge (ESD) robust semiconductor transistor (transistor) may include: a semiconductor substrate of a first conductivity type; a substrate contact region of the first conductivity type coupled with the semiconductor substrate; a source region of a second conductivity type coupled with the semiconductor substrate; a channel region of the second conductivity type; a gate region of the first conductivity type; a drain region including a first drain region of the first conductivity type and a second drain region of the second conductivity type, and; an electrical conductor coupled over the second drain region and a portion of the first drain region; wherein a portion of the first drain region is not covered by the electrical conductor and becomes a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and; wherein the transistor includes a silicon controlled rectifier junction field effect transistor (SCR JFET).
Implementations of an ESD robust semiconductor transistor may include one, all, or any of the following:
The first conductivity type may be P type conductivity, the second conductivity type may be N type conductivity, the channel region may include an N− channel region, and the transistor may include an N− channel SCR JFET.
The semiconductor substrate may include a P type substrate, the substrate contact region may include a P+ substrate contact region, the source region may include an N+ source region, the gate region may include a P+ gate region, the first drain region may include a P+ drain region, and the second drain region may include an N+ drain region.
The electrical conductor may include a silicide.
The resistive electrical ballast region may have a width of at least 3 microns.
The resistive electrical ballast region may form a separation layer between the electrical conductor and an electrically insulative region.
The transistor may have a stadium shape.
Implementations of an electrostatic discharge (ESD) robust semiconductor transistor (transistor) may include: a semiconductor substrate of a first conductivity type; a first substrate contact region of the first conductivity type coupled with the semiconductor substrate; a source region of a second conductivity type coupled with the semiconductor substrate; a channel region of the second conductivity type; a gate region of the first conductivity type; a drain region having a first drain region of the first conductivity type and a second drain region of the second conductivity type; a second substrate contact region of the second conductivity type coupled with the semiconductor substrate, and; an electrical conductor coupled over the second drain region and a portion of the first drain region; wherein a portion of the first drain region is not covered by the electrical conductor and becomes a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and; wherein the transistor includes a silicon controlled rectifier junction field effect transistor (SCR JFET).
Implementations of an ESD robust semiconductor transistor may include one, all, or any of the following:
The first conductivity type may be P type conductivity and the second conductivity type may be N type conductivity, wherein the channel region includes an N− channel region, and wherein the SCR JFET includes an N− channel SCR JFET.
The semiconductor substrate may include a P type substrate, the first substrate contact region may include a P+ substrate contact region, the source region may include an N+ source region, the channel region may include an N− channel region, the gate region may include a P+ gate region, the first drain region may include a P+ drain region (P+ anode), the second drain region may include an N+ drain region, and the second substrate contact region may include an N+ substrate contact region (N+ cathode).
The electrical conductor may include a silicide.
The resistive electrical ballast region may have a width of at least 3 microns.
The resistive electrical ballast region may form a separation layer between the electrical conductor and an electrically insulative region.
The transistor may have a stadium shape.
Implementations of an electrostatic discharge (ESD) robust semiconductor transistor (transistor) may include: a semiconductor substrate of a first conductivity type; a substrate contact region of the first conductivity type coupled with the semiconductor substrate through a first well region of the first conductivity type, the first well region separating the substrate contact region from the semiconductor substrate; a source region of a second conductivity type coupled with the semiconductor substrate; a second well region of the second conductivity type coupled with the semiconductor substrate; a drain region having a first drain region of the first conductivity type and a second drain region of the second conductivity type; a gate region, and; a silicide coupled over the second drain region and a portion of the first drain region; wherein a portion of the first drain region is not covered by the silicide and becomes a resistive electrical ballast region having a width of at least 3 microns, the resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses, and; wherein the transistor includes a silicon controlled rectifier field effect transistor (SCR FET).
Implementations of an ESD robust semiconductor transistor may include one, all, or any of the following:
The SCR FET may include a laterally diffused metal-oxide semiconductor (SCR LDMOS) transistor.
The first conductivity type may be P type conductivity and the second conductivity type may be N type conductivity.
The semiconductor substrate may include a P type substrate, the substrate contact region may include a P+ substrate contact region, the first well region may include a P well region, the second well region may include an N well region, the source region may include an N+ source region, the gate region may include an N+ gate region, the first drain region may include a P+ drain region, and the second drain region may include an N+ drain region.
The first well region may fully separate the substrate contact region from the semiconductor substrate and the first well region may directly contact the semiconductor substrate.
The second well region may fully separate the first well region from the semiconductor substrate.
The foregoing and other aspects, features, and advantages will be apparent to those artisans of ordinary skill in the art from the DESCRIPTION and DRAWINGS, and from the CLAIMS.
Implementations will hereinafter be described in conjunction with the appended drawings, where like designations denote like elements, and:
This disclosure, its aspects and implementations, are not limited to the specific components, assembly procedures or method elements disclosed herein. Many additional components, assembly procedures and/or method elements known in the art consistent with the intended electrostatic discharge (ESD) robust transistors and related methods will become apparent for use with particular implementations from this disclosure. Accordingly, for example, although particular implementations are disclosed, such implementations and implementing components may comprise any shape, size, style, type, model, version, measurement, concentration, material, quantity, method element, step, and/or the like as is known in the art for such ESD robust transistors and related methods, and implementing components and methods, consistent with the intended operation and methods.
Referring now to
The configuration (P type, N type, etc.) of the semiconductor substrate may be manufactured using any number of doping, diffusion, and/or annealing steps, or the like, with a silicon substrate, by non-limiting example. As will be described below, the transistor further includes electrically insulative regions, drain regions, gate regions, source regions, substrate contact regions, and the like, each of which may have different electrical and/or other properties. The different regions may be formed by any number or combination of masking (photoresist), exposing, etching, washing, doping, implanting, diffusing, annealing, and/or other steps, using appropriate materials and dopants, and the like.
The transistor 2 includes source, gate, drain, and channel regions. The channel region may be an N− channel region 16. The gate, source, and drain regions are all coupled with (and, in the implementations shown, are in direct contact with) the channel region, thus electrical current may flow between the source and drain through the channel and may be controlled by the gate. The source region (labeled “Source” in
The drain region (labeled “Drain” in
A number of electrically insulative regions 18 separate the source, gate and drain at the surface of the transistor. The electrically insulative regions may be formed of, by non-limiting example, Sift, or any other electrically insulative material.
Although the various regions in the representative example are formed of particular material types, i.e., a P type substrate, N+ source region, P+ gate region, P+ substrate contact region, P+ drain region (P+ anode), N+ drain region, N− channel region, silicide region, and so forth, other material types and combinations could be chosen by the practitioner of ordinary skill having similar or different electrical or other properties as desired (for instance beginning with an N type substrate and choosing the other material types accordingly).
As can be seen from
In the close-up view on the right hand side of
An N+ cathode region 52 is included (leftmost item labeled “Sub” in
The N+ source region 32 (labeled “Source” in
The configuration (P type, N type, etc.) of the substrate of transistor 28 may be configured utilizing any number of doping, diffusion, and/or annealing steps, or the like, with a silicon substrate, by non-limiting example. The various electrically insulative regions, drain regions, gate regions, source regions, substrate contact regions, cathode regions, and the like, each of which may have different electrical and/or other properties, may be formed by any number or combination of masking (photoresist), exposing, etching, washing, doping, implanting, diffusing, annealing, and/or other steps, using appropriate materials and dopants, and the like.
Although the various regions of transistor 28 are denoted by particular material types, i.e., a P type substrate, N+ source region, P+ gate region, P+ substrate contact region, P+ drain region (P+ anode), N+ drain region, N− channel region, silicide region, N+ cathode region, and so forth, other material types and combinations could be chosen by the practitioner of ordinary skill having similar or different electrical or other properties as desired (for instance beginning with an N type substrate and choosing the other material types accordingly).
As indicated to some extent above, the resistive electrical ballast regions are buffer regions or layers between the gate/source and the drain and help to increase the robustness of the device to damage from ESD. In implementations the resistive electrical ballast region 50 could be even greater, such as up to about 10 microns, in width. However, in experiments a 6 micron width for the resistive electrical ballast region (separation layer) 50 did not show notable improvement in ESD robustness over a 3 micron width. Simulation data indicated that the effect of a 1 micron width resistive electrical ballast region (separation layer) 50 was much less effective than a 3 micron width region, and that the protection from a 5 micron width region was similar to that of a 3 micron width region. Thus it appears that the protective benefits may be located in a range of widths of about 3-5 microns.
In various implementations, the transistor is an ultra-high voltage device and the depletion layer, at several hundred volts of operation, must extend about 100 microns in depth. In such circumstances it may be desirable to have a P type semiconductor substrate instead of an N type semiconductor substrate. An alternative may be to form a thick P epitaxial layer on an N doped substrate, but in such a case the overall thickness may need to be more than 100 microns and may make this option less desirable.
The configuration of transistor 28 shows an improved ESD robustness for an ultra high voltage (800 V) silicon controlled rectifier junction field-effect transistor (SCR-JFET). Although there have been laterally diffused metal oxide semiconductors (LDMOS) with a silicon controlled rectifier (SCR) structure that have exhibited acceptable ESD robustness, achieving ESD robustness in the ultra high voltage range (>800 V) has remained a challenging issue.
Most of the ESD surge current flows not from the N+ drain region but from the P+ drain region (P+ anode of the SCR), thus the extension of the P+ drain region creates an effective resistive electrical ballast region (separation layer) 50 that increases the ESD robustness. The addition of the resistive electrical ballast region 50 does not greatly alter the size of the overall device. In a representative example the diameter of a reference device without the resistive electrical ballast region 50 was 410 microns, and the width of the resistive electrical ballast region 50 was 3 microns, so the overall diameter of the altered device was 416 microns. The area penalty for the addition of the resistive electrical ballast region 50 is negligible.
HBM robustness of an 800 V SCR-JFET transistor 28 with the resistive electrical ballast region 50 was measured and compared with a similar 800 V SCR-JFET without the resistive electrical ballast region 50. Both transistors had a same drain width of 1900 microns. HBM robustness was improved from about 2000 V to 6000 V by implementing the resistive electrical ballast region 50
The transistors described herein may be used in a variety of product such as, by non-limiting example: off-line pulse width modulation (PWM) controllers for consumer and computing power supplies; 700 V startup product families such as adapters, flat TVs, low power, LED lighting; HB drivers, as a power transistor, and the like.
Referring now to
In transistor 54, a PNPN path exists from the P+ drain region (P+ anode) 12, through the N− channel region 16, through the P type substrate 4 or the P+ gate region 8, then via the N− channel region 16 to the N+ source region 6 which acts as an N+ cathode, and therefore transistor 54 forms a silicon controlled rectifier (SCR) structure. Transistor 28 also has a PNPN path similar to transistor 54 from P+ drain region (P+ anode) 38, through the N− channel region 42, through the P type substrate 30 or the P+ gate region 34, then via N− channel region 42 to the N+ source region 32 which acts as an N+ cathode, and therefore transistor 28 forms a silicon controlled rectifier (SCR) structure. Transistor 28 forms another PNPN path from the P+ drain region (P+ anode) 38, through the N− channel region 42, through the P type substrate 30, and through the N+ cathode region 52. Thus there are two current paths that allow the SCR structure in transistor 28. The N+ cathode region 52 allows the N+ source region 32 to not be grounded, which in implementations may result in more flexible circuit design.
In implementations, most of the current may go through the P type substrate but in other implementations the P+ gate may form a portion of a PNPN path as described above.
The N well region and P well region are next to one another and a source region 62 resides above (and is in direct contact with) the P well region. In implementations the source region is an N+ source region. A P+ substrate contact region 66 also resides above (and is in direct contact with) the P well region. The P+ substrate contact region 66 is coupled with the P type substrate through the P well region and the P well region fully separates the P+ substrate contact region from the semiconductor substrate.
The drain region of the transistor 58 includes a P+ drain region (P+ anode) 68 and an N+ drain region 70. A number of electrically insulative regions 76 are located at the upper surface of the device and between the various other elements and contacts, and may include SiO2 or some other electrically insulative material. A silicide 78 covers all of the N+ drain region and a portion of the P+ drain region, and may be formed of any electrically conductive silicide material. A resistive electrical ballast region (separation layer) 80 is thus formed, and operates similarly to others described herein by increasing the ESD robustness of the transistor. In implementations the resistive electrical ballast region (separation layer) 80 may have a width ranging from 3-10 microns. In implementations the resistive electrical ballast region (separation layer) 80 has a width of at least 3 microns. The resistive electrical ballast region forms a separation layer between the silicide and an electrically insulative region 76 of the transistor. Transistor 58 is an LDMOS transistor.
As used herein, “conductivity type” refers to either P type (including P, P+, P−) and/or N type (including N, N+, N−) conductivity.
As disclosed above, and referring again to
Referring still to
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Still referring to
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Still referring to
Examples of conventional transistor designs may be found in the following references, each of which is entirely incorporated herein by reference: Fujiwara, S., Nakaya, K., Hirano, T., Okuda, T., Watanabe, Y., “Source engineering for ESD robust NLDMOS,” published at 33rd Electrical Overstress/Electrostatic Discharge Symposium (EOS/ESD), 11-16 Sep. 2011, Anaheim Calif., pg. 1-6; Pendharkar, S., Teggatz, R., Devore, J., Carpenter, J., Efland, T., Chin-Yu Tsai, “SCR-LDMOS: A novel LDMOS device with ESD robustness,” published at The 12th International Symposium on Power Semiconductor Devices and ICs, 2000, pg. 341-344; Jung-Ruey Tsai, Yuan-Min Lee, Min-Chin Tsai, Gene Sheu, Shao-Ming Yang, “Development of ESD robustness enhancement of a novel 800V LDMOS multiple RESURF with linear P-top rings,” published at TENCON 2011-2011 IEEE Region 10 Conference, pg. 760-763, 21-24 Nov. 2011; Chin-Yu Tsai, Taylor Efland, Sameer Pendharkar, Jozef Mitros, Alison Tessmer, Jeff Smith, John Erdeljac, Lou Hutter, “16-60V Rated LDMOS Show Advanced Performance in an 0.72 um Evolution BiCMOS Power Technology,” published in Technical Digest of International Electron Devices Meeting (IEDM) 1997 by IEEE, p. 367-370, disclosed at conference proceedings at least as early as 10 Dec. 1997 at Washington, D.C., and; Jeffrey Smith, Alison Tessmer, Lily Springer, Praful Madhani, John Erdeljac, Jozef Mitros, Taylor Efland, Chin-Yu Tsai, Sameer Pendharkar, Louis Hutter, “A 0.7 um Linear BiCMOS/DMOS Technology for Mixed-Signal/Power Applications,” Published in Proceedings of the Bipolar/BiCMOS Circuits and Technology Meeting 1997, p. 155-157 by IEEE, disclosed at conference proceedings at least as early as 30 Sep. 1997 at Minneapolis, Minn.
In places where the description above refers to particular implementations of ESD robust transistors and related methods and implementing components, sub-components, methods and sub-methods, it should be readily apparent that a number of modifications may be made without departing from the spirit thereof and that these implementations, implementing components, sub-components, methods and sub-methods may be applied to other ESD robust transistors and related methods.
Fujiwara, Shuji, Burton, Richard Scott
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